<scp>ELISA</scp>‐type assays of trace biomarkers using microfluidic methods

Dong, Jinhua; Ueda, Hiroshi

doi:10.1002/wnan.1457

Cited by 44 publications

(23 citation statements)

References 87 publications

(160 reference statements)

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“…ELISA is a plate-based assay technique designed for detecting and quantifying antibodies or proteins. ELISAs are typically performed in well plates but microfluidic approaches have also been investigated [87]. In a bubble-driven micromixer within a microreaction well the detection of a biomarker in bladder cancer patients’ urine only required 30 to 40 min compared with the 3 to 4 h required for a conventional ELISA [88].…”

Section: Micromixing Methodsmentioning

confidence: 99%

Microfluidic Magnetic Mixing at Low Reynolds Numbers and in Stagnant Fluids

et al. 2019

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Microfluidic mixing becomes a necessity when thorough sample homogenization is required in small volumes of fluid, such as in lab-on-a-chip devices. For example, efficient mixing is extraordinarily challenging in capillary-filling microfluidic devices and in microchambers with stagnant fluids. To address this issue, specifically designed geometrical features can enhance the effect of diffusion and provide efficient mixing by inducing chaotic fluid flow. This scheme is known as “passive” mixing. In addition, when rapid and global mixing is essential, “active” mixing can be applied by exploiting an external source. In particular, magnetic mixing (where a magnetic field acts to stimulate mixing) shows great potential for high mixing efficiency. This method generally involves magnetic beads and external (or integrated) magnets for the creation of chaotic motion in the device. However, there is still plenty of room for exploiting the potential of magnetic beads for mixing applications. Therefore, this review article focuses on the advantages of magnetic bead mixing along with recommendations on improving mixing in low Reynolds number flows (Re ≤ 1) and in stagnant fluids.

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Section: Micromixing Methodsmentioning

confidence: 99%

Microfluidic Magnetic Mixing at Low Reynolds Numbers and in Stagnant Fluids

et al. 2019

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“…They all require costly equipment, disposables, reagents, highly qualified personal and involve comprehensive sample preparation procedures; only ELISA was introduced to clinical practice. Though recently microchip-based platforms based on ELISA were created for several protein biomarkers [37], no such devices have been reported yet for the uromodulin analysis in urine or plasma.…”

Section: Introductionmentioning

confidence: 99%

Label-Free Protein Detection by Micro-Acoustic Biosensor Coupled with Electrical Field Sorting. Theoretical Study in Urine Models

Mukhin

Коноплев

Oseev

et al. 2021

Sensors

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Diagnostic devices for point-of-care (POC) urine analysis (urinalysis) based on microfluidic technology have been actively developing for several decades as an alternative to laboratory based biochemical assays. Urine proteins (albumin, immunoglobulins, uromodulin, haemoglobin etc.) are important biomarkers of various pathological conditions and should be selectively detected by urinalysis sensors. The challenge is a determination of different oligomeric forms of the same protein, e.g., uromodulin, which have similar bio-chemical affinity but different physical properties. For the selective detection of different types of proteins, we propose to use a shear bulk acoustic resonator sensor with an additional electrode on the upper part of the bioliquid-filled channel for protein electric field manipulation. It causes modulation of the protein concentration over time in the near-surface region of the acoustic sensor, that allows to distinguish proteins based on their differences in diffusion coefficients (or sizes) and zeta-potentials. Moreover, in order to improve the sensitivity to density, we propose to use structured sensor interface. A numerical study of this approach for the detection of proteins was carried out using the example of albumin, immunoglobulin, and oligomeric forms of uromodulin in model urine solutions. In this contribution we prove the proposed concept with numerical studies for the detection of albumin, immunoglobulin, and oligomeric forms of uromodulin in urine models.

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“…Sample and reagent fluids are able to flow in specially engineered channels ranging in several microliters, allowing more economical usage of healthcare resources. Miniaturization of the procedure reduces volumes of samples and reagents, risk of contamination and enhances detection limits, making the effects synergistic with those of the impedance-based immunoassay (10). Combining microfluidics with electrochemical immunoassays seems to have a promising role in the future of laboratory research since it enhances user-friendliness and lowers cost-rates (11).…”

Section: Introductionmentioning

confidence: 99%

Development of a label-free microfluidic impedimetric immunoassay for anti-SPAG16 antibody

Vreys

Thoelen

et al. 2021

Preprint

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A recently found biomarker regarding multiple sclerosis, namely the anti-SPAG16 antibody (Ab), could be a potential way for early detection, prognosis and diagnosis of said autoimmune disease. Merging electrochemical analysis with a microfluidic system is a novel approach, which avoids the use of labelling steps as seen in traditional ELISA immunoassays. In this study, aluminium interdigitated electrodes on polystyrene-coated PET foils were implemented in a microfluidic flow cell to bind and detect SPAG16 Abs by impedimetric measurements. The coated PET foils showed a clear affinity for the fusion protein SPAG16THIO and thioredoxin (THIO). Determining sensitivity and specificity of antibody-antigen binding using a microfluidic ELISA immunoassay has revealed the test to be unreliable by showing no linear pattern of a dilution series of the standard and producing skewed inconsistent results. The impedimetric analysis showed opposite results of what one would expect. The systems efficiency is in need to be revised and optimised before undergoing actual diagnostic tests. Further advancement could be done by reducing leakage, securing a more stable entrance for injection and circumventing the occurence of air bubbles in the wells.

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ELISA‐type assays of trace biomarkers using microfluidic methods

Cited by 44 publications

References 87 publications

Microfluidic Magnetic Mixing at Low Reynolds Numbers and in Stagnant Fluids

Microfluidic Magnetic Mixing at Low Reynolds Numbers and in Stagnant Fluids

Label-Free Protein Detection by Micro-Acoustic Biosensor Coupled with Electrical Field Sorting. Theoretical Study in Urine Models

Development of a label-free microfluidic impedimetric immunoassay for anti-SPAG16 antibody

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